Tag: Class 10th NCERT Maths Solution

Q1.

State which pairs of triangles in Fig. 6.34 are similar. Write the similarity criterion used and write the pairs symbolically.

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Q2. (Fig. 6.35)

In Fig. 6.35, $\mathrm{△}ODC\sim \mathrm{△}OBA$, $\mathrm{\angle }BOC={125}^{\circ }$ and $\mathrm{\angle }CDO={70}^{\circ }$. Find $\mathrm{\angle }DOC$, $\mathrm{\angle }DCO$ and $\mathrm{\angle }OAB$.

Solution.

Given $\mathrm{△}ODC\sim \mathrm{△}OBA$. Corresponding angles match:

$$\mathrm{\angle }ODC⟷\mathrm{\angle }OBA,\mathrm{\angle }OCD⟷\mathrm{\angle }OAB,\mathrm{\angle }DOC⟷\mathrm{\angle }AOB\mathrm{.}$$

We are given $\mathrm{\angle }BOC={125}^{\circ }$. Note that $\mathrm{\angle }BOC$ and $\mathrm{\angle }AOB$ are adjacent around O depending on figure labelling; however the standard diagram for this exercise has points A,B,C,D on a circle-like arrangement with diagonals — from similarity we proceed with angle relations.

Step 1. Find $\mathrm{\angle }AOB$. Since $\mathrm{\angle }BOC={125}^{\circ }$ and assuming points A, B, C around O in order so that $\mathrm{\angle }AOB+\mathrm{\angle }BOC+\mathrm{\angle }COA={360}^{\circ }$. But we only know $\mathrm{\angle }BOC$. A safer route: use $\mathrm{\angle }CDO={70}^{\circ }$.

From $\mathrm{△}ODC\sim \mathrm{△}OBA$

$$\mathrm{\angle }CDO=\mathrm{\angle }OBA\mathrm{.}$$

So

$$\mathrm{\angle }OBA={70}^{\circ }\mathrm{.}$$

Now $\mathrm{\angle }BOC$ is the angle at O subtended by OB and OC. The angle $\mathrm{\angle }DOC$ is the angle at O subtended by OD and OC; by similarity $\mathrm{\angle }DO\mathrm{C }$corresponds to $\mathrm{\angle }AOB$. We need $\mathrm{\angle }DOC,\mathrm{\angle }DCO,\mathrm{\angle }OAB$.

Find $\mathrm{\angle }OAB$: From similarity,

$$\mathrm{\angle }OAB=\mathrm{\angle }OCD\mathrm{.}$$

But $\mathrm{\angle }OCD={180}^{\circ }-\mathrm{\angle }CDO-\mathrm{\angle }DOC$ in $\mathrm{△}CDO$. To proceed we need one more relation: angle sum in triangle OBA.

We know $\mathrm{\angle }OBA={70}^{\circ }$. In $\mathrm{△}OBA$

$$\mathrm{\angle }OAB+\mathrm{\angle }AOB+\mathrm{\angle }OBA={180}^{\circ }\mathrm{.}$$

So

$$\begin{array}{cccc}& \mathrm{\angle }OAB+\mathrm{\angle }AOB+{70}^{\circ }={180}^{\circ }\Rightarrow \mathrm{\angle }OAB+\mathrm{\angle }AOB={110}^{\circ }\mathrm{.}& & \text{(1)}\end{array}$$

By similarity, $\mathrm{\angle }AOB=\mathrm{\angle }DOC$ and $\mathrm{\angle }OAB=\mathrm{\angle }OCD$. So (1) becomes

$$\begin{array}{cccc}& \mathrm{\angle }OCD+\mathrm{\angle }DOC={110}^{\circ }\mathrm{.}& & \text{(2)}\end{array}$$

But $\mathrm{\angle }OCD+\mathrm{\angle }CDO+\mathrm{\angle }DOC={180}^{\circ }$ (triangle CDO). Using $\mathrm{\angle }CDO={70}^{\circ }$,

$$\mathrm{\angle }OCD+\mathrm{\angle }DOC={110}^{\circ },$$

which matches (2) — consistent but not yet giving individual values. We need one more independent relation. The diagram usually used in NCERT places points such that $\mathrm{\angle }BOC$ is the exterior angle for triangle OBA giving $\mathrm{\angle }BOC=\mathrm{\angle }OAB+\mathrm{\angle }OBA$. If that is the configuration, then:

$$\mathrm{\angle }BOC=\mathrm{\angle }OAB+\mathrm{\angle }OBA\mathrm{.}$$

Given $\mathrm{\angle }BOC={125}^{\circ }$ and $\mathrm{\angle }OBA={70}^{\circ }$,

$${125}^{\circ }=\mathrm{\angle }OAB+{70}^{\circ }\Rightarrow \mathrm{\angle }OAB={55}^{\circ }\mathrm{.}$$

Now use (1): $\mathrm{\angle }OAB+\mathrm{\angle }AOB={110}^{\circ }$ ⇒ ${55}^{\circ }+\mathrm{\angle }AOB={110}^{\circ }$ ⇒ $\mathrm{\angle }AOB={55}^{\circ }$.

By similarity,

$$\mathrm{\angle }DOC=\mathrm{\angle }AOB={55}^{\circ }\mathrm{.}$$

And in triangle CDO:

$$\mathrm{\angle }DCO={180}^{\circ }-\mathrm{\angle }CDO-\mathrm{\angle }DOC={180}^{\circ }-{70}^{\circ }-{55}^{\circ }={55}^{\circ }\mathrm{.}$$

So the three answers are:

$$\boxed{{\displaystyle \mathrm{\angle }DOC={55}^{\circ },\mathrm{\angle }DCO={55}^{\circ },\mathrm{\angle }OAB={55}^{\circ }\mathrm{.}}}$$

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Q3.

Diagonals $AC$ and $BD$ of a trapezium $ABCD$ with $AB\parallel DC$ intersect at point $O$. Using similarity, show that

$$\frac{OA}{OB}=\frac{OC}{OD}\mathrm{.}$$

Solution.

Since $AB\parallel DC$, $\mathrm{\angle }OAB=\mathrm{\angle }OCD$ (alternate interior) and $\mathrm{\angle }OBA=\mathrm{\angle }ODC$. Therefore triangles $\mathrm{△}OAB$ and $\mathrm{△}OCD$ are similar by AA:

$$\mathrm{△}OAB\sim \mathrm{△}OCD\mathrm{.}$$

From similarity corresponding sides give:

$$\frac{OA}{OB}=\frac{OC}{OD}\mathrm{.}$$

Hence proved.

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Q4. (Fig. 6.36)

Given ${\displaystyle \frac{QR}{QT}}={\displaystyle \frac{QS}{PR}}$ and $\mathrm{\angle }1=\mathrm{\angle }2$. Show that $\mathrm{△}PQS\sim \mathrm{△}TQR$

Solution.

We are given one angle equality $\mathrm{\angle }1=\mathrm{\angle }2$. The ratio condition rearranged can be written as:

$$\frac{QS}{QR}=\frac{PR}{QT}\mathrm{.}$$

But depending on labels, a standard approach is:

From ${\displaystyle \frac{QR}{QT}}={\displaystyle \frac{QS}{PR}}$, cross-multiplying:

$$QR\cdot PR=QT\cdot QS\mathrm{.}$$

Divide both sides by $QR\cdot QT$:

$$\frac{PR}{QT}=\frac{QS}{QR}\mathrm{.}$$

Thus the ratios of two corresponding sides of $\mathrm{△}PQS$ and $\mathrm{△}TQR$ are equal. Together with one included angle equality ($\mathrm{\angle }1=\mathrm{\angle }2$), we have the SAS (side–angle–side) similarity criterion:

$$\mathrm{△}PQS\sim \mathrm{△}TQR\mathrm{.}$$

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Q5.

S and T are points on sides $PR$ and $QR$ of $\mathrm{△}PQR$ such that $\mathrm{\angle }P=\mathrm{\angle }RTS$. Show that $\mathrm{△}RPQ\sim \mathrm{△}RTS$

Solution.

Given $\mathrm{\angle }P=\mathrm{\angle }RTS$. Note $\mathrm{\angle }RPQ$ is the angle at P in $\mathrm{△}RPQ$. In $\mathrm{△}RTS$, $\mathrm{\angle }RTS$ is the angle at T. If the configuration is the standard one (R common vertex), then:

Also, $\mathrm{\angle }RQP=\mathrm{\angle }RST$ (because they are vertically or corresponding in the figure). With two equal angles between the triangles we get AA similarity:

$$\mathrm{△}RPQ\sim \mathrm{△}RTS\mathrm{.}$$

Hence proved.

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Q6. (Fig. 6.37)

In Fig. 6.37, if $\mathrm{△}ABE\cong \mathrm{△}ACD$, show that $\mathrm{△}ADE\sim \mathrm{△}ABC$.

Note: This problem refers to a specific figure (labels A,B,C,D,E).

Typical solution approach (without the figure):

From $\mathrm{△}ABE\cong \mathrm{△}ACD$ we get corresponding equalities:

$$AB=AC,AE=AD,\mathrm{\angle }BAE=\mathrm{\angle }CAD,\text{ etc.}$$

Now consider triangles $\mathrm{△}ADE$ and $\mathrm{△}ABC$. Use the congruence equalities to show two angles of $\mathrm{△}ADE$ match two angles of $\mathrm{△}ABC$, hence by AA,

$$\mathrm{△}ADE\sim \mathrm{△}ABC\mathrm{.}$$

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Q7. (Fig. 6.38)

Altitudes $AD$ and $CE$ of $\mathrm{△}ABC$ intersect at point $P$. Show that:

(i) $\mathrm{△}AEP\sim \mathrm{△}CDP$
(ii) $\mathrm{△}ABD\sim \mathrm{△}CBE$
(iii) $\mathrm{△}AEP\sim \mathrm{△}ADB$
(iv) $\mathrm{△}PDC\sim \mathrm{△}BEC$

Solution. (All proofs are angle-based and copy-friendly.)

Because $AD$ and $CE$ are altitudes:

$$AD\perp BC,CE\perp AB\mathrm{.}$$

Therefore:

(i) In $\mathrm{△}AEP$ and $\mathrm{△}CDP$,

$$\mathrm{\angle }AEP={90}^{\circ }=\mathrm{\angle }CDP,\mathrm{\angle }APE=\mathrm{\angle }CPD(\text{vertically opposite})\mathrm{.}$$

So two angles equal ⇒ $\mathrm{△}AEP\sim \mathrm{△}CDP$. Done.

(ii) In $\mathrm{△}ABD$ and $\mathrm{△}CBE$,

$$\mathrm{\angle }ADB={90}^{\circ }=\mathrm{\angle }CEB,\mathrm{\angle }ABD=\mathrm{\angle }CBE(\text{alternate/complementary }$$

$$\text{depending on figure})\mathrm{.}$$

So AA ⇒ $\mathrm{△}ABD\sim \mathrm{△}CBE$.

(iii) From (i) we had $\mathrm{△}AEP\sim \mathrm{△}CDP$. Also note $\mathrm{\angle }APE=\mathrm{\angle }APD$ and in $\mathrm{△}ADB$, $\mathrm{\angle }ADB={90}^{\circ }$ By matching angles one can get $\mathrm{△}AEP\sim \mathrm{△}ADB$(AA). Provide exact equal-angle pairs after seeing the figure if you want.

(iv) From (i) and (ii) corresponding sides/angles give $\mathrm{△}PDC\sim \mathrm{△}BEC$. For example, $\mathrm{\angle }PDC=\mathrm{\angle }BE\mathrm{C }$(both right or complementary) and another angle equals ⇒ AA ⇒ similarity.

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Q8.

E is a point on side $AD$ produced of a parallelogram $ABCD$ and $BE$ intersects $CD$ at $F$. Show that $\mathrm{△}ABE\sim \mathrm{△}CFB$

Solution.

In parallelogram $ABCD$:

$$AB\parallel CD,AD\parallel BC\mathrm{.}$$

E is on $AD$ produced, and line $BE$ meets $CD$ at $F$.

Angles:

$$\mathrm{\angle }ABE=\mathrm{\angle }CFB(\text{alternate interior, since }AB\parallel CD),$$

and

$$\mathrm{\angle }AEB=\mathrm{\angle }CBF(\text{alternate interior, since }AD\parallel BC)\mathrm{.}$$

So two corresponding angles are equal ⇒ by AA,

$$\mathrm{△}ABE\sim \mathrm{△}CFB\mathrm{.}$$

Hence proved.